Casting-machine.



Patented Apr. 29, |902.

m .Lm .R.m1. EHw. Druk EAR E V .m Gm IN Hln CNW D. M 5, no 9 6 D. N

m sheetssheet ("0 Mdel.)

fesses:

No. 69s ,59|. Patented Apr. 29,' |902.

f C. H. VEEDER.

CASTING MACHINE.

(Application mea Feb. 15,1900.)

l0 Shqets-Sheet 2.

(No Model.)

lffesses vh? mi nonms Pneus co.. Waremme., yvAsmNm'ou. Fm;

No. 698,59l. Patented Apr.l 29, |902, l C. H. VEEDER.Y

CASTING MACHINE.

(Appliaton led Feb. 15, 1900.)

S mllupnuum @a mum mlmlmm Fllllil TH: Nanals vsrzsslcolvnorournov.wAsmNnroN, n.12.

No. 698,59I.

(No Mudei.)

C. H. V'EEDEB. CASTING MACHINE.

(Application led Feb. 15, 1900.)

" wfl 5042777297:" @urns #a Patented Apr. y29, |902 No. 698,591. Pafemed Apr. 29, 1992. lc.'H. vEEnE|a. CASTING MACHINE.

l (Application filed Feb. 15, 1900.)

(N9 Model.) l0 Sheets-#Sheet` 5.

lhlllll M SQS , No'. e9a,5 9|. Patented Apr. 29, |9o2.=

c. H. vienes.

CASTING MACHINE.

' rgb. 15 19o .ij "i m .F'Ilr limi l Emmi Patented Apr. 29, |902. lc. H. vvJiEm-:FL CASTING MACHINE.

(Appneation med Feu 15, 1900,)

` l0 Sheets-#Sheef 7.

No. 698,59l.

v(No Model.)

i IIIIIIIIIV .Ip IIIIIIIIII e Tcs co.. PHOTO-Limo., wAsHwcroN, n, c.

'Patentg'd Apr. 29, |9702..A

No; 698',59l.

- n.11. vEEnfER. 4

CASTING MACHINE.'

(Application led Feb. 15;"1900.)

vI() Sheets-*Sheet 8.

Glo Mndel.)

THE Nonms Prrsns co., PHOTO-LWN() wAsmNcsToN, u. c4

No. 698,59l. Patented Apr. 29,` |902.

c. H. vienna. A

CASTING MACHINE.

(Application led Feb. 15,i 1900.)

lo sheets-sheet 9.

(No Model.)

Illjlll ma Nonms Enns co, vuomumm WASHINGYDN. D. c.

Nu.69a,59|. y Patented Apr; 29,1902.

` c. H. veeuen.

CASTING MACHINEE (Applicatio led Feb.' 16, 1900.5

l0 Sheets-Sheet l0.

A Mmmm Witnesses:

-to which reference maybe made".

ent invention embodies many'important feanm UNrfrnD PATENT OFFICE.

CURTIS II. VEEDR, OF HARTFORD, CONNECTICUT;

CASTING-MACHINE.

SPECIFICATION forming part of Letters Patent No. 698,591, dated April 29, 1902'.

Application led February 15, 1900. Serial No. 5,296. (No model.) p

To a/ZZ whom it may concern:

Be it 'known that I, CURTIS H. VEEDER, a citizen of the United States, residing in Hartford, in the county of Hartford and State of Connecticut, have invented certain new and useful Improvements in Casting-Machines, of which the following is a specification.

This invention relates to casting-machines, and has for its main object the provision-of a machinefor forming dense castings having faces `ofpsuch smoothness that the castings Will not need to be subjected to the usual operations of planing, turning, dre., but can be used and assembled with other parts with the bearing-surfaces in the condition in which they come from the molds and under conditions where exceptionally.well-finished bearing-surfaces are required in ordertopermit the proper movement of parts upon one another. This result I attain by employing a castingmachine so constructed and capable of operating insuch a manner as to condense the molten metal most perfectly during the making of the casting and before the completion thereof. I have found that the best results can be secured by producingr a vacuum, preferably of the kind known as a .highvacuum, in the mold into which the metal `is to be poured and then forcing molten metal under pressure into the exhausted mold until the mold is completely filled. When castings are formed in this way, all of the spaces and corners of the mold,`nopmatter how small they may be, are completely filled bythe molten metal forced thereinto, and the casting corresponds exactly in contour to the mold, every minute projection or` indentation in which is reproduced perfectly as an indentation or projection in the nished casting, no matter how complex the'pattern to be reproduced may be. Moreover, in every case cast-` ings formed in this manner are of a dense, homogeneous, and exceedingly tine crystalline structure throughout.

The present invention is in the natureof an improvement upon the inventions shown, described, and claimed in my applications, Serial No. 738,269, filed November 27, 1899, and Serial No. 2,435,1i1ed January 23, 1900,

The prestures of novelty not shown in leither of said applications, and the machine in which these features are embodied will preferably oper; ate entirely automatically in order that it may make castings at a high rate of speed without requiring any special care from an attendant.

i The molten metal may be delivered to the mold in many ways; but I prefer to inject it into the same under high pressure, so that the stream will be forced violently into every portion of themold. In the present case I have employed for this purpose mold-filling means in which a plunger of relatively large diameter exerts at the proper time a violent pressure upon a column of molten metal which is injected into the mold through a relatively small.opening,and hence at a high velocity. V In my prior application, No. 738,269, filed November 27, 1899, I have shown a mold lmounted in a vacuum-chamberin suchamanner as to be movable therein in different directions, while in my other application, hereinbefore referred to, I have illustrated a mold from which air is exhausted directly. In the present case I have retained the feature illustrated in the first of my prior applications, but in a very much improved form, and in the construction shown herein not only is the mold mounted in a vacuum-chamber, but much of the operatinggmechanism therefor is also contained within said chamber, the con- 4 struction being such that the principal operating devicesare all inclosed and work within a large chamber from which the air has been exhausted, these operating devices being controlled in this case from a source of .power outside such vacuum-chamber.

`When the principal operating devices are inclosed in a large vacuum chamber in the manner just stated, it is desirable to make `provision forobtaining access to the interior in operation and without impairingthe vacuum I consider within the scope of my invention.

Many other features of importance not hereinbefore mentioned will be set forth hereinafter in detail and are clearly illustrat-ed in the drawings accompanying this specification, in whieh- Figure lis a side elevation of an automatic casting-machine embodying my present invention. Fig. 2 is a plan of the same. Fig. 3 is a transverse section of the same, the section being taken in line Z) b, Fig. 5, lookingin the direction of the arrow. Fig. 4 is an end elevation of the machine viewed from the left in Fig. 2,parts of the framework being broken away in order to show the construction clearly. Fig. 5 is a substantially central vertical longitudinal section of the machine. Fig. Gis an enlarged plan of the central portion of the machine with the top of the vacuum-chamber removed and illustrates the principal operating mechanisms with the mold closed. Fig. '7 is a similar View with the mold open. Fig. S is an enlarged sectional plan of the central portion of the machine with the cover of the vacuum-chamber removed, the parts beying in the positions shown in Fig. 6. Fig. 9 is an enlarged substantially central Vertical longitudinal section of the central portion of the machine, With the parts in the positions shown in Fig. 5 and with the mold closed. Fig l0 isa similar View showing the positions of the parts when the mold is open. Figs. ll to 25, inclusive, are details illustrating cams employed for controlling the movements of the principal mechanisms and devices of the machine. Fig. 26 is an enlarged detail of the yielding rod for the casting-stripper.

Similar characters designate like parts in all the igures of the drawings.

As in the second of my applications, hereinbefore referred to, I have shown herein a complete automatic machine by means of which castings maybe formed and ejected from the machine regularly and at a high rate of speed without requiring any considerable amount of attention from an operator.

The several operative parts of my improved machine may be mounted on a suitable framework or bed, such as A, supported on legs in the usual manner and havinga main shaft 2, which may be driven by a band-wheel 3 from any suitable source of power, and from this shaft the movements ofl all of the automatically-operating parts of the machine may be derived. s

Any suitable means may be employed for melting and holding the metal from which castings are to be formed; butin the present case I have shown at one end of the framework a melting-pot, (designated in a general way by M.) The contents of this pot may be kept hot in any suitable manner, ordinarily byagas-jet. In the construction shown this melting-pot has a well 6, opening directly into a chamber 8, having at least two openings leading therefrom. One of these openings is indicated herein by 8 and is intended to receive molten metal from the tank at a point considerably below the surface of the metal and keep the chamber 8 and the lower part of thewell-that is,the portion below the pistonfilled with molten metal, the upper portion of said well being iilled in this case by molten metal entering through an opening 6 near the surface ofthe'molten bath. The otheropening in the chamber 8, which openingis designated herein by 10, serves as an outlet through which metal may be delivered to the mold at each operation. The chamber Sin lthe present case is formed partly Within and partly without the melting-pot M, a nozzle, such as l2, being secured to said melting-potin the construction shown and being so shaped internally as to contain a portion of the valve-chamber 8 and also the discharge-opening l0. This nozzle may be held in place by a screw-threaded clamping ring or nut, such as 12', and the latter may be secured in position within an opening at the discharge side of the melting apparatus by means of a clamping-ring, such as l2, secured in placein this instance by means of screw-bolts. These and other parts of the melting apparatus are preferably so constructed as to be readily removable to permit renewal thereof when worn or broken, and in the construction illustrated the plunger, hereinafter to be described, works in a well having a removable sleeve or bushing, such as 4, while the opening 8', through which molten metal passes to the valve-chamber 8, may be formed in an annular seat or bushing 5,which may be held in position by means of a screw-threaded holding ring or nut, such as 5. Moreover, it will be noticed that the well 6 opens vertically into the chamber 8, and thus serves to permit the escape of air and gas from said chamber, which if it accumulated would tend to reduce the compressing action and form blow-holes. I-Iere the melting-pot M is divided into two main parts, one, m, the melting-tank proper, and the other, m', including the well and the valve-chamber, hereinbet'ore described. This valve-chamber is preferably heated directly by one or more gasejets, which serve to keep the body of molten metal in such chamber in a state of most perfect iiuidity. In order to apply the heat to the Valve-chamber and the well to the best advantage,I may employ in connection therewith a casing which may comprise an annular member or shell 13, in which the threaded ring 12' is seated, and a thin casing member or plate, such as 13', adjacent to the wall of the melting-tank.

The mold-filling means is intended to lie partly within and partly without a vacuumchamber in which the mold will be mounted for movement, and in order to prevent ex` cessive conductionv of heat to the Walls of said vacuum-chamber I may employ in connectionA with the shell 13 a heat-insulating ring, such as 14, which may be of asbestos. I may also IDO IIO

circulate a cooling uid, such as. water, in contact with a wall of, this vacuum-chamber, this circulation being maintained in the present casethrough a channel in a ring 15, surrounding the member-13. These parts prevent overheating of the walls of the vacuumcharnber and form an air-tight expansion` joint, the parts of which are freely supported between the discharge-nozzle of the mold-filling means and one of the walls of the vacuumchamber, and hence are freely movable relatively to such associated members and are:

not held under restraint thereby, the parts of the expansion-joint being movable both lengthwise and crosswise of the longitudinal axis of such discharge-nozzle.`

For the purpose of controlling the flow of` moltenmetal to the mold I prefer to mount within the valve-chamber 8 and the openings 8 and` 10 a valve so constructed as to close. the opening 10 when a casting is not being` made. This valve may alsoserve to, open communication through thepassage 8' with the main body of metal in the melting-tank,`

and when so constructed as to accomplish both of these results constitutes a double-.action valve.

For the purposeof supplying a chargeof metal to the mold I preferto make use of mold filling means embodying a member which will act upon the metal in s'uc'h a manner as to force the molten charge under high pressure into the mold, and thus assure the Ordinarily a` plunger, such as p, will work lin the well 6,

filling of all corners thereof.

and when depressed will cause the metal to be injected in a small column or stream into the mold., M u r The plungerp maybe carried at the lower end of a plunger-rod 26, which may be mounted for vertical reciprocation in a support or bracket 27fastened to the upper side of the melting-potM, said plunger-rod being oper.1

ated `in this case by across-bar 27, removablyconnected therewith, said cross-bar hav-` ing pivoted thereto at opposite ends thereof a pair of connecting-rods, such as 29, the lower 4ends ofwhich are in turn connected to corresponding armsor levers 30 and 30", se-

cured to a rockshaft 30. The lever 30' is :in-` this case .an angle-lever, the other arm of.` rwhich is pivoted to a connecting-rod 3l, which. extends towardthe opposite end of the ma` chine and in turn ispivoted to the upper end` .of abifurcated lever` 31', suitably pivoted on the framework and having a block with a leto face 3l", adapted to coact with a corresponding quick-let-off face of a cam 33 on the main shaft 2. thereto one end of a coiled spring` 32, the

other end of which is fastened to afixed point and servesto force the plu ugerp down rapidly when the let-off face 3l rides down that of* the cam 33.

The valve .o is intended to reciprocate ini the chamber 8 and inthe openings 8f and 10,

and during a portion of a complete cycle of `versely to each other.

Said lever 3l has secured operations will be controlled in its movements by the molten metal in the valve-chamber and in the main portion of the melting-pot M, and will move back and forth in accordance with the flow of` the metal in the one direction or the other; but during another portion of the cycle of operations it is intended in this case that the valve shall be controlled positively and held shut. These parts just described will be so constructed and preferably will so close the same,as shown in Fig.` 9, I may make use of any suitable valve-operating mechanism, but here I have illustrated at 35 a rockarm carried by a rock-shaft 35, mounted in suitable bearings and` also controlled inits movements by the mainshaft 2. The connections to this shaft may be any suitable for the purposebut` in this case are somewhat `similar to those previouslydescribed yfor operating the plunger. A rock arm (not shown) secured to this rock-shaft-is pivoted, in this instance at itsfree end, to one end of a connecting-rod 36, the opposite end ofwhich in turn is pivoted to the upper end of a lever "37T, substantially similar to the lever 31 and pivoted in a similar manner to the framework.

IOO

AThis levert, 37 may be bifurcated-- and `may carry an antifriction-roll 37', adapted to cooperate with a cam 4l on theshaft 2, said cam i having a small wiper 41 projecting therefrom I for shifting the rock-'arm 35 away frolnthe valve momentarily when acasting is to "be made.

antifriction-roll 37 in contact with thecam close the valve o and cut` off the metal to the mold.

. l Au important feature of my present invention is the employment, in connection with- 2 mold-fillin g means and with a separable mold,

of mechanism for shifting the mold-sections relatively to eachother in diiferent directions at the proper times to open or close the mold, and the mold employed will usually embody end and side sections movable trans- In practice the walls ofthe sprue-hole become roughened and coated at the point where the molten metal `iirst enters, and it is very difficult towithdraw thesprue from a' solid mold at this point.- Hence I preferito make use of amold ,embodying a pair 0f side `sections constitut- .ing sprue-forming mold-sectionsmovable toward and from each other, while the body of A spring. 42, `connected to the leverI `37 and to axedpoint, serves to hold the .4l and to operate the rock-arm quickly to supply of the casting will be formed by the main portion of the mold, which will usually consist, of morethan one section, and in the construction` illustrated is, in fact, made up of a main section substantially 'xed relatively to the sprue-forming mold-sections and to theV other sections of theV mold and an end section and a core-section movable differentially in the same direction transversely to the paths of movement of the sprne-forming mold-sections.

Many different styles of molds may be employed in connection with my improved Inachine for formingcastings of`various shapes so long as the molds differ only in the shapes of the mold-spaces; but in the present case I have illustrated a mold embodying five moldsections adapted to be separated to the proper extent and in a predetermined order to per` mit the stripping of the completed casting therefrom. The mold shown is designated in a general way by O and has five mold-sections, two of which may be considered as the' main mold-sections and are designated, respectively, by o (here shown made up of more than one part, although its construction may be different) and o', (these main sections constituting end sections in the particular form of mold shown,) two others being sprue-forming side sections and being designated by o" and of, While the fifth section of the mold is the auxiliary Acore-section, which is desig-.

the separation or breaking of the sprue fromA such body portion.

All ofthe sections of the mold may be supported by mold-carriers, each mold-section in this case having a separate carrier on which it is supported and by means of which its movements. are controlled. Preferably one section of the mold, such as the section o,will

be mounted on a main mold-carrier or mold-l carriage properly guided on the framework for movement toward and from the discharge-y nozzle of the mold-filling means, and all of the other sections of the mold may be supported most advantageously by auxiliary mold-carriers mounted on and guided in their movements by the main mold carrier or carriage inorder that allof the various moldsections maybe positively located and guided during the movements thereof. Here the main mold-section, which may be made up of several parts, is fastened directly' to the main mold-carrier, which will preferably be in the form of a carriage or slide, such as H, movable lengthwise of the machine and properly guided by ways thereon, this carriage being in the present case a substantially T- shaped slide open at one end thereof and having guideways therein in which the rseveral auxiliary mold-carriers may be mounted for reciprocation. Of course this carriage may be made up of aV number of parts, and, in fact,

'it has been found advantageous to mount the auxiliary mold-carriers in guideways'in divided collars or bearings, such as 1S, 18', and 19. All of these mold-sections maybe ,supported by cylindrical auxiliary mold-carriers mounted for reciprocation on the main slide or carriage lengthwise and'crosswise of the latter, two of these auxiliary mold-carriers, such as h" and h'", supporting in this case the side sections or sprue-forming sections o and 0" of the mold, While a tubular carrier h' lnay support the mold-section o', and a cylindrical carrier h within the tubular car riage h' may support the core c of the mold.

The mold-carriers, and hence the mold-sections operated thereby, may be actuated in any suitable manner; but as one of the principal features of my present invention is the employment of a casting-machine in which the mold and much of its operating mechanism are contained within a vacuum-chamber and go through their cycles of operations in suoli chamber while the latter is exhausted I prefer to employ, in connection with the mold and the mold-filling means, operating means controlling the movements of some portion or portions of the mechanism within the vacuumchamber and preferably controlled in turn from a point without said chamber, which is designated herein in a general way by C. In the present case I have deemed it desirable to employ in connection with an operated member Within the vacuum-chamber, which operated member may be a mold-carrier or any other suitable part of the mechanism, an operA ating member Working in an opening in a Wall of the vacuum-chamber, a proper air-tight packing being interposed between this operatingmember and the walls of the opening in said chamber in order to prevent leakage of air thereinto. The employment in a casting-machine of a vacuum-chamber in Which the principal members of the mechanism for forming and stripping a casting are located is an importan t feature of my present improved machine, as it permits the maintenance of an almost perfect vacuum Within such chamber during all of the various stages of each cycle of operations of the mechanism. I-Ience in such a construction as the mold-sections close together whilel located in an exhausted space the mold-space itself will of course be an exhausted one before the mold-sections are closed. When these various mold-sections or other parts located Within the vacuum-chamber are operated by mechanical connections from a point without the chamber, it of course becomes necessary to provide means for permitting the movement of certain operating members in the walls of such chamber and yet prevent leakage of air into the latter through the openings in which such operating membersk work, and as this is also a matter of great practical importance I consider' within the scope of my invention any casting mechanism in which one or more of the op- ICO IIO

erated members within the vaeuuxn-chamber are controlled by operating means working in an opening or openings in the wallspof the l C, a suitable" air-tight packing, such as 52,`

`being interposed betweenV said rod and the Walls of such opening in order to prevent admission of air into said chamber. This operr ating-memberlisintended to be controlled `j inits operation `by the main shaft 2 and in this case ispivotally connected to aspring` pressed rod` or eyebolt 53, preferably adjust-`` ably secured to the upper portion of a swing-4 ing frame, (designated in a general way by f.) i This franiefmay be of any suitable construction, butin this caseembodies two pairs of` levers, r such as 54, pivoted on the fixed shafts washers,` such as 54..

or rods 38 and `3S' and properly spaced by `At the upper ends thereof these levers 54are pivoted to a block7 such as 54, which may be of composite coni struction, and has a lug, such as 54V', rising therefrom, through which the bolt 53 is passedand with which itis adjustablyconnected to regulate the `movements of the carriage H. In this case each pair of levers 54 carries anantifrictiou-roll, and these rolls are intend-` ed to coactwitha `earn 56`,\secured to the". main shaft 2, the advancing and retreating movements of the carriage H being effected by the swinging of the frame f, while the spring 53 tends to force the carriage toward the discharge-nozzle of the mold-filling means when the mold isclosed.

The mold-carriers hf and h" for'thesprue- H may be connected to swinging frames, such as forming mold-sectionso" and 0" may be operated by connections similar to those just'` described for operatingthe carriage H. In the present case said carriers are pivotally connected witha pair of angle-levers, such` as 57 and 57', by means of short links 5S and 58', said angle-levers being iu turn pivoted,` preferably adjuster-bly,` to connecting rods, such as 59 and 59', these connecting-rods be`` ing in this case adjustable by means of turnbuckles 59" therein and being pivoted to op-s erating members orrods, such as 60 aud 607,

passed through openings in a`wall of the vacu u1u-chamber C in snbstantiall y the same manner as is the operating memberl, said rods 60 and 60'` being pivoteddto spring- 'pressed rods or eyebolts 61 and 6l', similar to that shown at These bolts 61 and 6l" are connected to swinging frames f", sub stantially similar in most respects `to that shown at f, except that the lugs through Which the bolts 6L and 6l' pass are nearen the mold than is the lug on vthe `frame Moreover, the `springs 61761, surroundingthe bolts 6l and 61', normally tend toforce4 chamber C.

movement thereof.

said bolts to the right, as seen in Fig. 2', while the spring 53' tends to force its bolt to the left, as seen in said view. The swinging frames f" are operated by cams coacting with antifriction-rolls in substantially the same manner as hereinbefore described with reference to the frame f. I- Iere antifriction-rolls, such as 62 and 62', coact with corresponding cams, such as 63 and 63', (see Fig.`4,) on the main shaft 2 to operate said frames f", and hence the mold carriers 711" and h", at the proper times. Both of these cams may be of the construction shown in Figs. 17 and 18. From each of the other two moldfcarriers 7L 4and 7L I deem it advantageous to make a more direct connection to the operating members therefor, and in the present instance leach of these carriers is controlled by a forked arm secured to an operating member working in an opening inA a wall of the vacuum- Here these operating` members are in the form of rods 64 and 65, similar to r t the others hereinbefore described, and each of said rods is preferably screw-threaded at its inner end to receive a divided collar and permit adjustment of a forked arm adapted when properly adjusted to befirmly clamped in place on its operating-rod. These forked arms are designated herein by 6G` and- 67, respectively, and span reduced portions, which may be formed by grooves in `the rearends of the carriersh and h,"asclea1-ly.shown in Fig. 8-Th`ese operating-rodseiand 65 arealso intended to be controlled directly by the shaft `2, and the connections between said rods and the shaft may be substantially the t same as IOO thos'ebefore describedlwitli referenceto the" main carriage and the mold-carriers for the sprue-forming side sections ofthe mold." Here said operating-rodsi and are pivoted, re-

spectively, to spring-pressed connecting-rods or eyebolts, such asSand 69, which inturn IIO ffandfr, constructed andoperatingsubstantially in the same manner as the other swing- `ing frames hereinbefore described.` `Here the frame f has antifrictionrolls, such as 70,

which coact with a cam 71 onthe shaft 2, while theswingingframef"f has corresponding antifriction-rolls 72, which coperatewith a cam 73 on said shaft. Itgwill be apparent `operating members 6e and 65`inward toward the mold instead of tending to pull them outward away from said the rods 60 and 60". r. 'r V 0f course the core-carrier or core-rod it mold, asis the case with vshould be capable of moving relatively to the `auxiliary mold-carrier or Ashell hi', and in this case theshell has a `pin`75, which1 passes through a corresponding slot `7G in the corerod h (see Figs. 8` and 9) and serves to guide the core-rod and determine the range of It will be evident that all of the" various connections `between the shaft 2 and the moldsections may be positively controlled in their positions and movements by means of the various adjustments hereinbefore referred to and clearly shown in the drawings. Hence the positions of the mold-sections may be posiltively determined and the perfect closing of the mold and the opening of the same to the proper extent assured. Not only are these mold-sections positively held together and the mold firmly held against the face of the discharge-nozzle of the mold-filling means, but the springs surrounding the operating members that pass through the walls of the vacuum-chamber serve as means for exerting upon the mold-sections during the filling of the mold separate and continuous pressures in directions transverse to each other, two of the springs pressing in one direction to hold the sprue-forming side sections of the mold together, while the other springs operate in the opposite direction and serve to force the carriage, the core-rod, and the shell toward the discharge-nozzle with Vvaryimgf pressures and in a path perpendicular to the paths of movement of the side sections. The operations of these parts are so timed that after a casting has been formedv the sprue-forming mold-sections o" and 0" will open iirst, after which the shell and the core-rod willwithdraw simultaneously from the main section o, and thereafter the core-rod will Withdraw still farther to the position shown in Fig. 10, it being understood, of course, that before any of the mold-sections separate the mold as a whole should be withdrawn, at least to a slight distance, from the discharge-nozzle of the mold-filling means, the movement of themaincarriage II serving to effect this result. It-will be evident, therefore, that not only do lIfmake use of a separable mold embodying a n plurality of mold-sections, but that in connection therewith I employ mold-separating mechanism for shifting said mold-sections in different directions to open the mold and effect the stripping of the casting therefrom.

Ordinarilya pair of side sections-in this case the sprue-forming sections of the moldwill b e shifted simultaneously in opposite directions, and v'thereafter' one or more end sections will be shifted in a different direction, these -end sections, if there is more than one, being shifted. dierent distances in such direction. This mold-separating mechanismfis intended to cooperate with certain other elements in the construction shown in the lpresent case, and one of these elements is a sprue-separating device for parting the sprue and the casting, this device being effective only after the sprue-forming mold? vsections have been opened, and hence after the mold-separating mechanism has operated `to separate these particular sections of the mold.

The sprue-separating device may be of any suitable construction; but I prefer to make use of one by means ofwhich the sprue and the body of the casting Will be parted by breaking the former at a point close to the latter, and a sprue-separating device of this type is shown herein. Said device is designated in a general way by Z9, and is also located within the vacuum-chamber C, and will preferably be operated from the main sha-ft2 without said chamber. Hence the operating member, whichl passes through a wall of said vacuum-chamber, should have an air-tight packing interposed between it and the walls of such opening. Usually this sprue-separatingdevice will have a hard central operating end for breaking the sprue from the body of the casting and an outer brush-like portion serving as a means for cleaning the cheeks of the mold-sections, and hence said member serves as a combined sprue-separating device and mold-cleaning means. In this case it consists, essentially, of a working portion 80', havingabrush-like surface, the workingportion being carried by a body 8O in the form of an adjustable plate pivoted on an arm 8l, secured to a rock-arm 82, adapted to vibrate in an upward eXtension of the vacuum-chamber formed in a recess c' of the vacuum-chamber cover-plate. This rock-arm is fixed toa rockshaft 83, which passes through the wall of the vacuumchamber and through an air-tighty packing 83, and carries at its outer end a long rockarm 85, from which a connecting-rod S6 passes to a lever S7, mounted on the fixed shaft 38',

and having a roll portion (not shown) adapted to enter the cam-groove of a cam 88, secured to the main shaft 2. The arm Sl of the device just described may be guided in its vmovements by means of a link 89, pivoted within the vacuum'-v chamber C and movable substantially in parallelism with the rock-arm 82.

In connection with' the device just described I-deem `it desirable to employ a casting-stripper which may be constructed and may operate in substantially the same way, except that whilevthe sprue-separating device is movable in a path between the sprueforming mold-sections the casting-stripper is intended to move in a path between the main sections of the mold by which the-body of the casting is formed. The casting-stripper is designated in a general way by s and in the construction shown embodies a hookshaped stripping member 90', secured to an adjustable body or plate 90, pivoted on a carrier-arm 91, pivoted in turn to a rock-arm 92, secured to a rock-shaft 93, journaled in bearings in substantially the same manner as and in alinement with and forming a continuation of the rock-shaft 83, said shaft 93 passing through a stuffing-box 93 in the Wall of the vacuum-chamber C and having at its outer end a 'rock-arm 95, similar to that shown at 85. This rock-arm 95 is in this case pivoted to a connecting-rod 96, the other end of which is pivotally connected to a lever 97, mounted on the shaft 38', and having a roll portion (not shown) adapted to work in the IOO IIO

cam-groove of a cam 98, secured to the main shaft 2. The rod 96 is made in two parts, as shown in Fig. 26, having stops ,96" and 96m," respectively, with acompression-spring 96' between them in order to permit the rod to4 yield should the casting in descending strike` an obstruction, such as an improperly-adjusted mold-section. Said rod will of course be rigid when it raises the stripper and will positively operate thelatter. The arm 91 of the casting-stripper may alsobe guided in its movements by means of a link 99, pivoted thereto and t"`o the inner side of the vacuumchamber C, said link being movable substantially in parallelism with the rock-arm. 92.,

4Hence the casting-stripper and its operating connections are actuated in. substantiallythe same manner as the combined sprues`eparat` ing device andbrusli and the operating-connections therefor; but `it should be understood that the devices?) and s are successively effective in that order, owing tothe fact that thesprue-forming mold-sections:willseparate before` the main sections of the mold are; opened. j y, i

Another feature which I' deem of importance is the employment, in connection with lthe devices bereinbefore described, of means for scraping olf `metal which sometimes adheres very firmly and `becomes soldered `to, those portions of the mold `Whichconne in con- "tact with the nozzle. `In order to remove this metal and assure atight `joint and `prevent clogging, I have employed apair ofi fixed scrapers mounted on the carriage H and in `position to `scrape" the cheeks oflthetsprueg formingmolds`ections `when the latter arel separated. These fixed moldfscrapers, which are designated herein byl'OO, are disposed oppositelyl to eachother "in a com mon fplane l in suchpositions that when the sprue-forming mold-sections are separated the forward. cheeks 4ofjthe latterxvill move across the edges of the mold-Scrapers, and any particles of cast metal which" may have adhered tothe mold-sections willfbe scraped off to enable` -the sectionsto 4close tightly against thefface e of theA discharge-nozzle whenanother casting is tobe formed.

filling means, and theoperating Ineclianism for positioning one of these elements relatively to the other an electromagnetic safety device whichcoperates with such position- 'l ingmechanism and is effective reciprocally therewith-that is to say, when the mechanism for positioning one of such elements is not effective for locating the same properly `the safety device will be effective for preventing the introduction of molten metal into the mold, and, vice versa, when the positioning mechanism is effective for locating the aforesaid element or elements properly the safety device will not be effective to block "the operation ofthe mold-lilling means, but will per- `mit the latter to inject the molten metal into by four of the mold-sections, the two sprueforming mold-sections serving toclose one of saidzbreaks,`as shown in Figs. 6 and \7,whil e the main sectiony o and `theend section o' of the mold serve to close the other break. In the specificiconstruction shovvnIbave illustrateda battery b', from which a conductor "passes to the electromagnet 106 oflan electromagnetic safety device, (designated in.

a general way by 6,) and from :this electromagnetanotber conductor 107 passes to the mo1d.section`o",` which has a contact-face in the` plane of the meeting faces" of the mold-` sections o'f ando". `This contact-faceis adapted to make contact Withacorrespond- `ing contact-face'on themoldpsection o", from` which a short conductor 108 leads tothe moldsection o, the contact-face on the conductingwire beingadapted in this case to be received in a shallowrecess 109 inthe mold-section o in,electricalcommunication' with a contact.- post 110on the framework, from which a `short conductor 112 passes to` a switch 113, the switch-arm 113 of Whichi's connected by means of another short conductor 114"to the `other pole ofthe battery `b'. The switch 113 may `have a pair of stop-pins for limitingthe `movements of the switch-arm. y It will be apparentnour that so long as the mold-sections are not fully closedthe circuit `vvill not be closed, and hence an electromagnetically-controlled locking device,` such"` as the armature 115e, having the usualgoverning-spring. s and'serving to controltheoperation ofthe plunger p, will not"be attracted by the electromagnet, but will serve to block `the operation of theplunger-operatingmechl anism and in this case will lie in the path of ,y

a stop` 116V onthe rod 31, while When said electromagnet is energized saidpawl 1 15`willbe Withdrawn from the path of movement of such TOO IIO

stop and will permit the spring 32 to operate said connecting-rod 31 and through it the plunger p. (See Fig. 1.) l

It will be apparent from the foregoing that the employment of a vacuum chamber in which the mold and the other principal cooperating parts are located is one of the most important features of my present invention. This vacuum-chamber may be of any snitable construction and of any proper size, pro- Vvided that it is large enough to receive the various operating parts which. are intended to be contained therein, and it should be so constructed as to preventleakage of air thereinto at those points where-operating parts of the mechanism pass through the walls of the chamber. Usually this vacuum-chamber will be a large one, occupying substantially the ,whole'central portion of the machine, and it may be made in several parts, the present construction illustrating a two-part casing closed by al removable cover. This cover is .designated ina general way byc and the upper and lower portions of the chamber by c and 0". (See Figs. 3, Il, and 5.) The upper and lower portions of t-he vacuum-chamber may be permanently connected by means of screw-bolts or in any other suitable manner;

but the cover c should be readily detachable from the upper portion c" of said vacuumchamber, and hence the covermay be held in place most advantageously by means of screw-clamps, such as 120, which when screwed tight will seal securely the joint between the cover and the section c". -As this cover is quite lheavy in a full-sized machine, it will be foundv desirable to provide a screweye, such as12l, by means of which the cover may be lifted. It should be understood, of course, that the vacuum-chambershould be exhausted as completelyas possible before the machine begins lto operate, the chamber being exhausted ordinarily through a pipe,

. suchlas 122, by means of an exhaust-pump.

(Not shown.) In order to observe the operation of the mechanism, large sight-openings may beformed in the Walls of the chamber C,

preferablyin the cover c', and these openings will have transparent air-tight closures, such as 123. Y

When castings are vformed in a mold located within a vacuum-chamber, it will be evident that provision should be made for effecting the removal ordischarge of the completed castings'from the vacuum chamber .from time to time Without impairing the vacuum in suoli chamber. In order to accom- .plish this result, I have made use herein of -casting receiving and discharging means which will control an opening in a wall of the vacuum-chamber and will always ,seal

.said opening, so as to prevent the admission of air into the chamber, and yet will serve alternately to receive castings and discharge the same from the vacuum-chamber. This vacuum-maintaining means for receiving and l discharging the castings will preferably employ a liquid seal for closing the opening through which the castings are delivered from the vacuum-chamber and will ordinarily be in the form ofV a large valve controlling a correspondingly large outlet-opening from the vacuum-chamber, which opening will usually be located directly below the mold in-order that the castings may drop by gravity. Moreover, in order to prevent injury to the castings the casting-receiving means will ordinarily have a chamber in one side thereof containing water or other liquid, into which the castings may fallwithout being injured. In thepresent case this casting receiving and discharging means is in the form of' a large plug-valve, such as V, having a chamber open at one side onlyv and of Aconsiderable size in order that it may receive .lof caps, one of which may completely inclose one end of the valve, while through the other the valve-stem may project, a suitable airtight packing being interposed between the Yvalve-stem and the walls of the opening in such cap. Here the cap through which the valve-stem 125' projects is designated by 126, while the other cap is indicated at 127, a stuflng-box 128 being interposed between the valve-stem 125 and the opening in the cap 126. This valve may be adjusted toward or from its seats by means ot'V a stem 125, having .adjustingand check nuts thereon, the opening throughwhich said stem projects being securely sealed by a small screw-cap, such as 129. A hand-wheel, such as 130, may be mounted on a stem. 125.in order to permit the turning'of the member V to its casting-receiving and casting-dischargingpositions alternately. Moreover, as it is desirable to prevent the unsealing ofthe lower end of the vacuum-cham- ,ber I prefer to make use of means for positively limiting the oscillatory movements of the casting-receiving means, `and `for this reason I have shown at 125'" a stop projecting from thevalve and adapted to cooperate with another stop 126 on the inner side of the cap 126, thesestops being so positioned and of such size as to limit the oscillations of the barrel to an arc considerably less than a complete circle. The reason for this will be lapparent by referring `particularly to Fig. 3, Vfrom which it will be seen that the vacuumchamber has at its open lower end a pair of vcut-off faces 135and 136, with which the solid IOO IIO

portionror cut-off face of the valve V coperates, and that if the barrel V were permitted to turn to the left from the position shown `in Fig. 3 the openingwould almost immediately be unsealed andthe vacuum in the chamber() destroyed as soon as the edge of `the opening passed` below the lower edge of the cut-off plate 135, when the `atmospheric pressure on the `water in` the receptacle R would force the water andair up` into the vacu tim-chamber to balance the pressures inside and outside said chamber. When,` however, the barrel lis turned to the right from the position shown in said figure, the castingcontainingmember maybe oscillatedthrough a very large arcto a pointwhere its contents will be discharged, and-thiswill take place while the opening between the upper ends of the `cut-off faces 135 and 136 is entirely sealed by the cut-0E faceof thevalve V. i i

Of course it will be apparent that whether awater-cushion is employed to check the fall `of the castings and prevent injury thereto and to format the Sametime an air-tightseal for the opening at the lower end'of the vacuumchamber is immaterial, provided that the `parts coperateto prevent leakage of air into the chamber C. It is preferable, however, to employ this water seal and also to make use of a receptacle, suchfasR, into which the castings in the chamber 125 may be distom of the receptacle R to receive the castings. discharged from the' chamber'125and permit the removal-thereof. Itwill be understood that the member V shouldbe oscillated` i to its casting-discharging position only at the `times when castings are noti-being formed,

as if this were not the case the castings would strike against the cut-O face of the receiving member and might be damaged.l In

light castings andthose made from alloys which water would injure awater sealn'eed not be used.

The operation of a machine constructed in accordance with my'presentinvention, as

direction of the arrow shown in Fig.` 1. There- A upon the ca m 73willbecome effective andthrough lits operating connections `will move the core c forward towardits closed position. Immediately thereafter the cam 71 will begin to move the shell h and the mold-section o riage H will shift the latter forward toward fthe face of the discharge-nozzle 12.

The sprue-forming `mold-sections o" and 0 will vreach their closed positions before the others and .will'close one break inthe circuit con- #trolling the operation of the safety device for preventing improper operation of the moldfilling means, and this safety device, it should be understood, will at this time be in position to block the descent ofthe plunger p. Fig. l.) l After the side sectionsof` the mold close the core c andthe end sectiono will alsoclose upon the main section o of themold practically simultaneously, and immediately thereafter the carriage will reach the limit of its forward movement, and theforward faces of themold-sections o and 0"' will be pressed irmlyagainsttheface of the discharge-noz- `zle 12, it being understood that at this time -all of the springs surrounding the connecting-rods pivoted to the operating members that pass through the walls of the vacuum-l chamber will Vbe exerting their forces-upon the several sections of the mold and thefcarriage H andthat the mold-sectionsiwill be pressed together and into close contact with the face-of the discharge-nozzle by thecontin uous but independent anddiiferential pressures exerted by the respective springs.` On

the proper closing of the end section o' ofthe mold the second break inthemelectric circuit to the safety device will be` closed and the electromagnet 106 will attract its armature and withdraw the stop-face thereof from the path of movementofthe stop 116onthe con- `necting-rod 31.1` The cam l10n` the Y shaft 2 willthen become eective to operatethe `rock-arm 35 through* the connections there- Atoandwill permit the valve@ to "open the passage 10, so that molten metal `may be -forced into thelmold by the plunger p, if the Vpawl 115 is out of the path ofthe stop 116.

If theseparts are properly positioned, thelet- -oif face 31@l of the lever 3L' willride down the 4let-oface of the cam 33 immediately after 4the rock-arm'35' is drawn back to permit the opening of the valve mand whensaid-let-o face on the lever passes the corresponding face on the cam 33 the spring-32 will force the plunger p down and a charge of `molten (See IGO

metal will be forced into the mold Oiand will `fill the same. Of course thevalvem opens the passage 10 only long enough to permit the charge tobe forcedinto the mold, and said passage is closed almost immediately,iand the 'plunger after reaching the limit of its down`- `wardmovementbegins to rise again.- All of the sections of the mold remain in their closed positions long enough for the casting to cool Ioo n properly, whereupon the cams 56, 7l, and 7S through their operating connections begin to withdraw the mold-carriers H, h', and h, and the latter simultaneously begin to move slowly in unison away from the nozzle l2. During this. movement the cams (53 and 63 become effective to separate the sprue-forming sections o and 0" of the mold, and thesel sections are rapidly separated and reach their wide-open positions at substantially the same time that the carriage reaches the limit of its rearward movement. At about this time the cam 88 becolnes effective to force the combined sprue-separating device and mold-cleaning brush b downward, and this device descending quickly between the open sections 0'/ and 0 of the mold breaks the sprue at a point adjacent to the body of the casting and after reaching the limit of its downward movement rises slowly in order that it may clean the mold-sections thoroughly. After the carriage reaches the limit of itsrearward movement the cam 71 continues to operate the shell 7L and the mold-,section o withdraws the body of the casting from the mold-section o, so that the casting will clear the latter, this shell therefore having a continued movement relative to the carriage after the latter has reached its extremev rearward position. The core c is then stripped from the casting by a continued rearwardv movement relative to the shell and to the carriage, this continued movement of the core being eifected by the last portion of the camface of the cam 73. The core reaches its extreme rearward Wide-open position with respect tothe other sections of the mold at about the Sametime that the brush reaches its extreme upward position after cleaning the mold-sections. During the last part of the movement of the core the casting-stripper s descends quickly and, striking the body of' the casting, strips the latter from the face of the end section o of the mold, if said casting has not already dropped into the casting-receiving member at the bottom of the vacuumchamber. This casting stripper is almostv immediately withdrawn from between the mold-sections, and after it rises to the limit of its upward movement the parts will be in positions to go through a new cycle of operations. Of course as soon as the sprue-forming sections of the mold separate the electric circuit will be broken and the safety device will return to its blocking position.

Having described my invention, I claiml. In a casting-machine, the combination with means for subjecting a mass of molten metal to a pressure greater' than atmospheric, of an outletnozzle through which molten metal is discharged; ashiftable mold; a vacuurn-chamber in which the mold is located;` means for advancing the mold to a position:

.when a casting is to be made in which it con-VA thereto; means for exhausting said vacuum-n chamber and thereby exhausting the space extending from the valve to the bottom of the mold space proper and through and into which the molten metal passes during its flow; a power-drivendevice in the machine, and mechanism operatively connected with such device for actuating the means for advancing the mold, thereby causing same to assume a casting position; then actuating the valve to admit molten metal under pressure to the exhausted mold and subsequently shut off all communication of the metal therewith, and finally actuating the means for withdrawing the mold, thereby withdrawing the mold from its casting position.

2. In a casting-machine, the combination with means for subjecting a mass of molten metal to a pressure greater than that of atmospheric, ot' a shiftable mold; a vacuumchamber in which the mold is located; a studing-box in a wall of the vacuum-chamber; a mold-actuator extending through the stuffingbox; a valve independent of the mold for controlling the entrance of molten metalthereto;

means for exhausting the vacuum-chamber and thereby exhausting the space extending from the valve to the bottom of the moldspace; a power-driven device inthe machine, and mechanism operatively connected with such device for actuating the mold-actuator, thereby causing the mold to assume a casting position; then actuating the valve to admit molten metal under pressure to the exhausted mold, andsubsequently shut ott all communication of the metal therewith, and finally again actuating the mold-actuator to withdraw the mold from its casting position.

3. Ina casting-machine the combination with a melting-tank and an outlet-nozzle through which molten metal is discharged, of a well communicating with said tank; a plunger for subjecting molten metal therein to pressure; a valve device embodying ,a pair of valve parts for simultaneously closing communication between the well and the melting-- tank and opening the passage through the nozzle, and vice versa; a shiftable mold; a vacuum-chamber in which the mold is located; means for advancing the mold to its casting position and't'or withdrawing it therefrom; means for exhausting the vacuum-chamber .and thereby exhausting the space extending from the valve part controlling the passage through the nozzle, to the bottom of the moldspace; a power-driven device in the machine, and mechanism operatively connected with such device for actuating the means for advancing and withdrawing the mold, the plunger and the valve device in proper order.l

4. In a casting-machine, the combination with a melting-tank and an outlet-nozzle through which lmolten metal is discharged, of awell communicating with said tank; aplunger for subjecting molten metal therein to pressure; a valve device embodyinga pair of valve parts for simultaneously closing com- ICO IIO 

